Refrigerating mechanism



Jan. 31, 1939. c. MUFFLY 2,145,777

REFRIGERAT ING MECHANI SM 6km Muff/g.

A TTORNEYS Jan. 31, 1939. G, MUFFLY 2,145,777

v REFRIGERATING MECHANISM Fued Aug. 2e, 1935 s sheets-sheet 2 G/enn Nuff/g ATTORNEYS Jan. 31,1939. GMUFFLY y 2,145,777

' REFRIGERATINCTA MECHANISM' .l

Filed Aug. 26, 1935 8 Sheets-Sheet 5 INVENTOR ,4 TT'ORNE Ys 77M @m4/a,

Jan. 31, 1939. G, MUFFLY 2,145,777

REFRIGERATING MECHAN I SM Filed Aug. 26, 1935' 8 sheets-Sheet 4 G/en Muff/i A TTORNEYJ Jan. 31, 1939'. G MUFFLY 2,145,777

' REFRIGERATING MECHANISM Filed Aug. 26, 1935 8 Sheets-Sheet 5 240'@ aA o o 2da 'o @S /enn Muff/q f V Ton 1&9/

ATTORNEYS Jan. 31, 1939. G. MUFFLY I REFRIGERATING MECHANISM Filed Aug. 2e, 1935 8 Sheets-Sheet 6 A TTORNE Ys `Ian. 31, 1939. G MUFFLY l 2,145,777

` REFRIGERATING MECHANISM vFiled Aug; 26, 1935 8 Sheets-Sheet 7 l Tuvn IN MINUTES o /o 2o o so eo L@ l n TINIE. IN MINUTES TIME N MINUTES 5o 6o /oo //0 /zo ATTORNEY Jan. 31, 1939. v G, MUFFLY REFRIGERATING MECHANISM Filed Aug. 26, 1955 8 Sheets-Sheet 8 3 1/ s MN/ R 3 hmm. m N m 6 a BY 4W 1% .?.r. .7. lm.. J

Patented Jur-31, 1939 PATENT 'o1-FICE ausm immaginiamo mcnmsm Glenn Mim. Birindelli. h10 Application mut zo, im, serbi No. :use

12 Claims.

IThis invention relates to mechanical refrigerating mechanism and particularly to the application of such systems for the artificial production of ice, and has particular relation to a simplified control mechanism for producing the lcycles of freezing and freeing blocks of ice in ice making apparatus of the general type disclosed in my copending applications forLetters Patent of the United StatesSerial No. 697,124,

- filed November 8, 1933; Serial No. 719,099, filed April 5, 1934, and Serial No. 737,485, filed July 30, 1934, and in which certain features shown and described herein are broadly claimed.

Objects of the invention include the provision 16 of means for cyclic operation of a refrigerating system in which the idle time of the condensing unit is utilized for effectively freeing the ice blocks most recently formed from their locations l of freezing; and to provide a refrigerating sys-v tem control mechanism inwhich a single thermostatic element effects both the cycling of the ice maker and the cycling of the condensing unit.

Other objects of the invention are to provide, in combination with a. refrigerating system, heat exchange means for preventing'the frosting of a flexible memberemployed in a valve structure thereof; to provide fiat surface evaporator units y v,m control thereof by means of a single thermally responsive element associated. with two or more refrigerant conduits; to effect the operation of the control mechanism between two temperature limits of which the higher limit is represented 4;, by cabinet air temperature and the lower limit is represented by refrigerant vapor temperatures; and to combine heat exchange means between two or more refrigerant conduits with Valve means regulating the iiow of refrigerants in the system.

vOther objects are to provide in a refrigerating system of the type described, an improved form of water tank and cover so arranged that the cover may be pushed backward in opening the l 5 tank and ythus provide ready access to the tank without removing the cover; and to provide actuating and clamping means of novel form for the tank cover.

Other objects are to provide a novel form of refrigerant evaporator unit having fins integral 5 with the surface which contacts a water 4tank so that better and surer defrosting to free the ice blocks formed within the tank is obtained; and to provide a refrigerating system of the type described having an improved support and spring 10 mounting for the evaporators thereof.

Other objects of the invention are to provide a mechanical refrlgerating system so constructed and arranged as to freeze bars of ice in such a manner that they are easily broken up into i small blocks on natural fracture lines; and to provide a triple valve of improved and simplified form foruse in connection with a mechanical refrigerator ice maker employing three sets of evaporator units of which Itwo are defrosting while one is refrigerating for the purpose of making ice.

l A further object is to provide an -improved type of refrigerator cabinet, particularly adapted for use in connection with the type of ice maker above mentioned, and having an inner form conducive to the natural flow of air over the cold surfaces of the refrigerating system cooperating therewith.

The above being among the objects of the present invention the same consists in certain novel features of construction, combinations of parts and step or steps of operation to be hereinafter described with reference to the accom panying drawings, and then claimed, having the above and other objects in view.

In the accompanying drawings which illustrate suitable embodiments of the present invention and in which like numerals refer to like parts throughout the several different views, 40

Fig. 1 is a fragmentary front elevational view of a refrigerator cabinet, with door open, showing the-cooling elements and control mechanism for the refrigerating system in place.

Fig. 2 isa fragmentary vertical sectional view 45 taken -on the line 2--2 of Fig. 1, with the door closed and showing the cooling and control elements of the refrigerating system mainly in elevation, the water tank being partially broken away to disclose ice floating therein. 50

Fig. 3 is a diagrammatic view of the refrigerating system employed in the construction illustrated` Figs. 1 and 2, showing the path of flow of the refrigerant.

Fig. 4 is an enlarged front elevational view 55 of the control switch and valve mechanism shown in the previous views.

Fig. is a view of the mechanism shown in Fig. 4, taken from the left-hand end thereof as viewed in Fig. 4.

Fig. 6 is a. view similar to that shown in Figs. 4. illustrating a slight modification thereof in which the two functions of the control mecha.- nism may be separated to produce a slightly different cycle of operation.

Fig. 7 is a partially broken, partially sectioned front elevational view of a modified form of control mechanism performing the same functions as the one shown in Fig. 4, but combining therewith the function of heat exchange between liquid and vapor refrigerant.

Fig. 8 is an enlarged detail view of the switch incorporated in the mechanism shown in Fig. 7, in closed position.

Fig. 9 is a view similar to Fig. 8 but showing the switch in open position.

Fig. 10 is a partially broken, partially sectioned side elevational view of a control mechanism identical with that in Fig. 7, but connected with two bulbs instead of with one as in Fig. 7.

Fig. 11 is a partially broken, partially sectioned side elevational view of a modified form of valve mechanism adapted to control three evaporator sections instead of two.

Fig. 12 is an enlarged view of the switch and ratchet mechanism shown in Figs. 7 to 10, inclusive, but modified for use with the triple valve shown in Figs. 11 and 13.

Fig. 13 is a vertical sectional view of the mechanism shown in Fig. 11, taken on the line I 3-i 3 thereof.

Fig. 14 is a partially broken, partially sectioned top plan view of a valve and switch control assembly similar to that shown in Fig. 4, but employing a triple valve construction similar to that shown in Fig. 11'.

Fig. 15 is a partially broken, partially sectioned side elevational view of the device shown in Fig. 14. with the cover 256 removed, showing parts 248, 250, 25| and 252 in section on line I5-I5' of Fig. 14, while the valve assembly below these parts is shown in section on line I5-I 5 of Fig. 14.

Fig. 16 is a bottom view of the triple valve shown in Fig. 15, with the cover 241 removed.

Fig. 17 is a partially broken, partially sectioned side elevational view of a gear drive which may be substituted for the lthermally actuated levers and ratchet devices seen in previous views for the purpose of actuating the valve mechanism on a timed cycle instead of on a thermally controlled cycle.

Fig. 18 is a horizontal sectional view taken on the line Iii-I8 of Fig. 17.

Fig. 19 is a side elevational view, partly in section, showing a refrigerator cabinet and a slightly modified arrangement of parts therein, including the cover mechanism for the tank, the ns in pairs integral with evaporator units, and rounded sharp freezer to allow better air flow.

Fig. 20 is an enlarged, partially broken, partially sectioned side elevational view of a fragment of the structure shown in Fig. 19, showing a section through one of the evaporator units to illustrate the integral n construction.

Fig. 21 is a sectional view taken on the line 2|-2l of Fig. 20, showing the rocker shaft and spring support for the evaporator units.

Fig. 22 is amore or less diagrammatic view showing a block of ice as it might be frozen during a prolonged period of operation on one BALL??? section of the evaporator shown in Figs. 19, 20 and 2l, illustrating the lines of easy fracture.

Fig. 23 is a diagrammatic representation of a hook-up suitable for operation of three evaporator sections in a refrigerating system by means of a triple valve mechanism.

Fig. 24 is a graph showing typical temperature curves of a dual valve refrigerating system having two evaporator sections for ice making and using a, separate thermostat such as seen in Fig. 6.

Fig. 25 is a similar graph showing curves for a system using the type of control seen in Figs. 4, 7 and 10, with an idle period following each freezing period.

Fig. 26 isa graphic chart of temperatures obtained in a triple evaporator ice maker employing a triple valve which is actuated independently of the thermostatic switch, as by the gear drive seen in Figs. 17 and 18, or with the thermally actuated triple valve and a separate thermostatic switch controlling the operation of the motor which drives the compressor.

Fig'. 27 shows a fragmentary vertical sectional view taken through a form of refrigerator cabinet particularly adapted for promoting a thermal circulation of airA suitable for the functioning of the type of refrigerating systems shown in the preceding views, the cabinet having its liner rounded at the rear upper corner to just clear the rear of the water tank cover when it is pushed back for access to the tank.

Fig. 28 is a vertical sectional view taken through the cabinet shown in Fig. 27 as on the line 28-28 thereof, showing how the cabinet liner is rounded at the top of each side to facilitate air flow over the tank and fins and to avoid the warm upper corners found in most refrigerators.

Fig. 29 is a fragmentary top plan view of the refrigerator cabinet shown in Fig. 27, showing the curvature of the inverted L portion of the door. v

Fig. 30 is a fragmentary vertical sectional view taken through a modied form of cabinet structure in which the insulation is curved along with the cabinet liner and a removable condensing unit occupies the space between the insulation and the outer shell.

Fig. 31 is a top view of the structure shown in Fig. 30 with the cover 346 removed, showing the arrangement of the condensing unit therein.

Fig. 32 is a fragmentary vertical sectional view ,taken on the line 32-32 of Fig. 30.

Fig. 33 is a fragmentary front elevational view of the cabinet shown in Figs. 30, 31 and 32 illustrating the form of door employed.

' 'I'he present invention deals particularly with mechanism for continuously producing a supply of artificial ice and while the invention in its broader aspects is capable of application to refrigerating units of any desired size, it is particularly adaptable to those sizes of devices employed for domestic purposes and for that reason the f the lwater within the tank, whereby upon resumption of the refrigeration of such walls or wall areas additional masses of ice will be again frozen thereonrto be later freed therefrom and float upwardly in the water of the tank to comingle with the ice previously frozen. By this type of apparatus a constant supply of small individual masses of ice may be continually maintained in the water tank from which they may be readily dipped as desired whenever required for use. Additionally the water itself is maintained at a relatively low temperature. Thus the construction and arrangement is preferably such that the body of water in the tank does not itself attain a sumciently low temperature to cause it to be frozen as a whole and as a result the individual masses of ice caused to be formed and to float upwardlyvtherein are maintained in a relatively free conditon with respect to each other which permits their ready removal and use. Because of-the fact thaty the bulk of the water in the water tank does not drop in temperature sufficiently to freeze the entire body thereof, the ice thus formed will continue to melt slowly, but it will be understood that any ice thus melting serves to replenish the main body of `Water from which the masses of ice are formed and, therefore, it is only necessary to replenish such water in the tank as may have been removed through ice actually removed from the tank, or water withdrawn from the tank for drinking orv other purposes.

In order to admit of propersanitation of devices of the type described and particularly where employed for domestic purposes, it is important that the water tank be readily removable for cleaning purposes and proper provisions are made to this end in accordance with the present invention.

It will also be understood that in refrigerators of the types herein under discussion, such refrigerators comprise a cabinet affording a suitably heat insulated chamber within which articles of food or the like may be stored for their proper preservation. Heat is extracted from the chamber by'means of a suitable refrigerating mechanism and While, in the broader aspects of the present invention, the particular type of refrigerating system is immaterial, that is. to say whether it is of the mechanical compression type or of the absorption type, the former is shown Iby way of simplicity of illustration. In such a type of'refrigerating mechanism it will be understood that a suitably driven compressor is I provided for compressing the expanded and gasied refrigerant yand discharging the same to a suitable condensing unit where, under the iniluence of pressure and reduction of temperature, the refrigerant is changed to its liquid phase. The liquid refrigerant from the condenser, or

. 'from a receiver when associatedtherewith, is y conducted in liquid' state to one or more suitable evaporators where the pressure upon `it is reduced and it is permitted to expand, thereby to absorb heat, and when it has been so expanded or gasied it is thereupon returned to the compressor where it is again compressed and its heat means are provided whereby but one section of said evaporator or evaporator units i's refrigerated at one time, the remaining sections or evaporator units being allowed to absorb heat during such time whereby to insure any ice which may have formed on the associated wall or wall areas of the water tank melting free from such wall or wall areas and be displaced therefrom,lthereby to condition such wall or wall, areas for the freezing of additional masses of ice thereon. All the levaporators or evaporatorsections are successively subjected to such a refrigerating effect and subsequent rise in temperature so that all combine to provide an approximately continuously replenished supply of ice in the tank.

One of the mainl features of the present invention is the provision of a mechanism of the type described and control means therefor by the use of which not only is refrigeration of a particular evaporator or evaporator unit discontinued by stoppage of the dow of refrigerant through it during continued operation of the refrigerating system so as to permit the ice formed on the associated wall or wall area of the tank to melt free therefrom, but additionally toinsure idle periods of the refrigerating system augmenting the warming period of each individual evaporator v 'manufacture than in the constructions disclosed in my prior applications above identified.

The control means operable to extend the warming up periods of the individual evaporators or evaporator units also forms an important feature of the present invention as do a number of other individual features of construction and arrangement of parts that will now be specifically described. y

Referring to Fig. 1 a refrigerator cabinet 5I is shown with the door opened or removed and a considerable part of the cabinet broken away. The ice and water tank 53 is broken away to show onlyits outline sothat the control parts located behind it are visible.. Below the tank is the sharp freezer 54 which is provided with insulated walls and with the insulated door 55. It is supported by the hangers 56 which also support rocker shafts 51, which in turn support the fins 58 which are part of the` evaporator units contacting the two angularly disposed fiat surfaces 59 of the tank 53. It will be understood that the liquid refrigerantA is first discharged into the low pressure side of the system in the evaporating means associated with the sharp freezer 54, and is then conducted tothe evaporator units of the ice making part of the system.

The evaporator units 60 (Fig. 2), of which five are located on each vside of the tank, are each formed with two rectangular contact areas 62l (Figs. 1 and 3) which contact the flat angularly disposed walls 59 of the tank to thereby supdisposed at angles of less than fortyfve degrees from the vertical, hence the tank by its wedging action between these surfaces, which support it, will bear upon the surfaces 62 with a total force considerably in excess of the proportional weight of the tank and its contents, thus insuring a good thermal contact between the tank and the evaporator units. Furthermore, because the units 60 are pivoted on the rocker shafts 51, and because the walls of the tank 53 are preferably formed from thin metal, the units may rock and the walls yield to insure full area of contact between all the areas 62 and the surfaces 59'of tank 53.

port it. It will be seen that the surfaces 59 are Due to the V formation of the lower part 'of the removable tank 53, it may be advisable in some cases to provide a support for tank 53 to make it more stable in its upright position when removed from the cabinet. One method of doing this is to attach the false front 13 to the tank 53 as seen in Fig. 2. This front plate has a width substantially equal to that of the tank to whichA it is rigidly attached and with which it is removable from the -cabinet. Being substantially ush with ythe bottom of the tank, this plate prevents sidewise tipping of the tank when placed on a flat surface such as a table top.

The door 52 (Fig. 2) is of the inverted L type which I have disclosed in co-pending applications hereinbefore identified. One of the refrigerant inlet manifolds 6| supplies the various evaporator units 60 on one side of the tank 53 with refrigerant of which a substantial part is still in the liquid phase, although under low or evaporating pressure. This refrigerant evaporates in the various evaporator units 60 on such side of the tank 53 and exits through the corresponding outlet manifold 63. Refrigeration of the evaporator units 60 causes heat to be extracted from the contacting walls of the tank 53 and from the water immediately adjacent such wall areas so as to cause such water to be frozen into ice. After ice has been frozen on the inner side of one of the angular wallsY 59 of the tank 53 the control |0| acts to stop refrigeration so that the ice blocks may be melted free from the wall by means of heat picked up by the fins 58 from the air Within the cabinet. In the meantime refrigeration will be produced in the evaporator units contacting the other angular wall 59 of the tank, as will be explained in more detail in connection with following views.

Fig. 3 shows diagrammatically the relationships between various parts seen in Figs. 1 and 2 and includes a representation of the high side or condensing unit of the system. Refrigerant ow may be traced in Fig. l3 asfollows: Refrigerant vapor leaving the left-hand manifold 63 passes through the tube 64, which contacts the bulb |03 of the control -|0|, to the coil 68 of the heat exchanger 66 and after passing through this coil is led by tube 10 to the valve assembly 15 into which it is free to pass because the valve 821 is lifted from its seat. This allows the refrigerant vapor Vto enter the housing 48| of the valve assembly, from which it exits through tube 1| to the suction side of compressor 86.

After refrigerant vapor has been compressed by the compressor 86 it is discharged through tube 88 to the condenser 89,*where it is liquefied and then drained into receiver 90. The liquid refrigerant leaves the receiver through tube 9| and' passes through the helically wound tube 92 of heat exchanger 66 in counter flow association with the vapor tubes 61 and 68. 'Ihe liquid gives up a considerable part of its specific heat to the vapor in the active tube 68 and then passes through the tube 93 to the pressure reducing device 94, which may be an expansion valve, a capillary restrictor,` a float valve or equivalent device.

The liquid refrigerant, now under reduced pressure, enters an evaporating coil (not shown) in the sharp freezer 54 from which it exits in partially evaporated state through tube 96 to the T 91 lat which point it is free to pass into whichever one of the manifolds 6| is active at the moment. It will be seen that if the rocker arm stem 18 of the valve assembly 15 were moved to the left about its pivot 11 by an angular pressure upon the point 19, the valve 82 would be closed and the valve 83 would be opened, since they are both mounted upon the valve rocker 16 associated with .the stem 18. This would change the path of refrigerant, causing it to flow from the T 91 through the right hand manifold 6| and the right hand set of evaporator units to the tube 65 and thence through the tube 61 of the heat exchanger 66 and the tube 69 to the valve port opened by the valve 83.

The rocker 16 of valve assembly 15 is actuated by means of spring pressure upon the point 19 or by mechanical means energized by control |0 as will hereinafter be explained in more detail. 'I'he control |0| also actuates a switch for closing the circuit through motor 81 by eecting contact between line wire III and motor wire ||0. The other line wire ||2 leads directly to the motor 81.

In Fig. 4 we see an enlarged detail view showing how the valve assembly 15 and the control assembly |0| are associated so that the former is actuated by the latter. For the sake of simplicity the thermostatic bulb |03 is shown contacting tubes 69 and 10 instead of tubes 64 and 65, thus omitting the heat exchanger 66 from this figure.

Valve 82 is shown open, hence refrigerant vapor is passing from the tube 10 to the tube 1| in the same manner as illustrated in Fig. 3. The circuit comprising wires 0 and is closed as seen in Fig. 4 due to the bellows |04 of the control |0| being expanded so that the arm |05 hasI swung upward on its pivot |06, compressing the spring |01 and tilting the mercury bulb switch |09 to its closed position. The compression of spring |01 is adjusted by means of a screw |08 to vary the temperatures at which switch 09 is opened and closed. The bellows |04 is responsive to the vapor pressure in the bulb |03 which is partially filled with a volatile liquid in accordance with conventional practice, and connected with the bellows by means of the tube |02.

Since it is considered that cold refrigerant vapor is passing through the tube 10. the vapor pressure in bulb |03 and bellows |04 is being gradually reduced so that finally the spring |01 will overcome the expansive force of bellows |04 and allow the arm |05 to tilt downward until the circuit including wires I0 and is broken by the mercury switch |09. Before the downward movement of arm |05 has caused the switch |09 to open it will have moved downwardly far enough to allow the push rod |2| to let the arm |23 rock in a clockwise direction under influence'of spring |24, raising the pin |26 at the left end of rocker |23 in turn lifting the pawl |21 until it falls into engagement with the next higher tooth of ratchet wheel |28.

After the circuit is broken in the switch |09 of control |0|, the motor 81 will be idle, hence no refrigerant will be drawn through any of the units 60 and no refrigerating effect will be pro. duced upon the bulb |03, which consequently warms up, approaching lthe temperature of the air, within the cabinet while this air temperature itself is also rising due to the stoppage of active refrigeration. This rise of temperature of the bulb |03 produces an increased vapor pressure within the bulb and vapor passing from the bulb through the tube- |02 to the bellows |04 vcauses the bellows to expand, compressing springs |01 and |24. The upward push `of the bellows transmitted to the rocker 23 causes it to move in a counterclockwise direction about its pivot |25, This exerts a downward push on the pawl |21 f causing the ratchet wheel |23 to move in a'l vcounterclockvlrise direction upon the flxed.stud

|23. The cam or star wheel |30 is secured to the ratchet wheel |23 and is rotated thereby upon the stud |23.

In the position shown'in Fig. 4 f the star wheel |30 is located with a tooth pointing towardthe roller |3| atv the right while the roller y|3| at the left has moved nearer to the star wheel |30 and is located between two teeth thereof. The spring |33, which is broken away in Fig. 4 but seen in full in Fig. 5, is compressed between the adjustably -flxed point |34 and the -movable point 13iof the valve rocker stem 13, thus holding thevalve 33 against its seat. The roller |3| at the left of star wheel |30 is not contacting the star. wheel, but there is a very small clearance between these parts so that the star wheel. |30 need be moved buta fewdegrees before it contacts' the roller |3| and begins to move .the fork |32 whichis rigidly attached to the valve rocker stem During the idle period ofthe condensing unit the bellows |04 is expanding, as before explained,

and this produces the movement ofv star'wheel |30 which causes the valve stem 13 to: move to 'the left until it passes the center linerand the spring |33 causes it to move farther to the left until stopped by the engagement of valve 32 with its. seat. Since the ratchet wheel |23 hasten teeth and the star wheel has ve teeth, a movement of one tooth on the ratchet wheel will bring screw, making the point adjustable sidewise on an arc about the lower screw. This provision is made so that the dead center line of spring |33' may be varied to obtain equal temperatures of operation for the movements to left and to right of the forkv |32. Such 'an adjustment has been found highly desirable in equalizing `the lengths Aof.'

idle periods after freezing on the right side andafter freezing on the left side. The point. |34 is also adjustable vertically to vary the compression of spring |33, thus providing an additional adjustment of the temperature at'which the valve mechanism is operated, u

Fig. 6 illustrates a yslightly modified arrangement of parts by means of whichrthe functions of the switch mechanism and of the valve mechanism may be separated to produce-cycles of the ice maker independently of the-cycles of condensing unitfoperation produced by a conventional thermostatic switch. The supporting member |35 l is the same as in Figs. 4 and 5 .and supports some of the same parts thereon, but is arranged differently in some respects and includes additional Y parts. The thermostatic switch |54, its tube |53,

and the bulb |52 perform their usual -functions of opening and closing contacts between thenwire- |'|0 and the wire in vrespons'eto temperature changes of the bulb |52, which is preferably located where it is affected by the temperature of air within the' refrigerator cabinet.

The bulb |40, replaces bulb |03 of Fig. 4 in contact with tubes 63 and 10, causing bellows |42 to |3| so that the next downward expand and contract with the changes of vapor pressure of a volatile liquid within the bulb |40. When the tube 1I drops in temperature, due to the start of '.frost-back" from the evaporator asl sembly with which this tube is associated, the bulb |40 is chilled and the bellows |42 contracts under the force of spring |41 which is powerful enough toy turn the lratchet wheel |23 through the medium ofthe pawl |21, thus snapping the valve mechanism to the left and opening valve 33 (Fig.

' 4). This action takes place during operation of the compressor and shifts the refrigerating effect to the opposite side of the tank independently of the thermostatic switch |54. v

The closing of the valve associated with tube (3.2 in Fig. 4) stops the now of cold refrigerant through tube 10 and allows bulb |40 to warm up, approaching the temperature of 'air within the cabinet, which expands bellows 42 and re-corn-` presses spring |41, lifting'pawl y|21 into a new notch of ratchet wheel |23. After the freezing operation has been completed on the side of the' tank now refrigerated the tube 63 will drop in temperature due to the start of frost-back and cause the bellows |42 to contract again, snapping the valve mechanism back to the position which allows flow of refrigerant through the tube 10 and closes the outlet port of the tube 63.

In either Fig. 4 or Fig. 6 the bulb (|33 and |40 respectively) might be in thermal contact with the assembly 15, say on bottom cover of the housing 3|, instead of contacting the two tubes 10 and 1|. The effect is substantially the same, but

slightly delayed, which calls for a slightly different adjustment of the control.

The screw |43 and its lock nut |49 are providedfor the purpose of adjusting the compression of the spring |41v to obtain the desired cycles of operation. The strength of the spring |41 and the setting of the screw |43 should be such that the valve mechanism will be actuated before 4enough frost has accumulated to interfere with the action of the bellows or to represent a material loss of refrigeration to the suction line 1|. On the other hand the setting of the screw |43 and the strength of the spring |41 .must be such that the pawl |21 is lifted into engagement with the next tooth of the ratchet wheel |23 during the warm-up period which follows each switch of the valve mechanism and before the freezing on the new side has progressed far enough to again start the frostingback which causes bellows contraction. The cycle of operation produced by a control as seen in Fig. 6 is further `explained by the graph shown lirl Fig. 24.

In Fig. 7 the bulb |03 is associated with the two tubes 33 and .10 for the same purpose as in Fig. 4, butin this view the tubes are shown coiled in parallel around the bulb |03. The bellows |60 acts in the same manner as the bellows |04 of Fig. 4, but is shown in inverted position and connected with a different mechanism, employing open contacts'instead ofthe enclosed mercury :type of switch shown in Fig. 4. The

types of switchmechanisms and contacts might vary greatly without departing from the spirit of this'invention, hence I show only two types of switches; the mercury bulb type, which may be actuated by a slow movement, and a springsnap type, which produces a sharp break of the current by mechanical means. Itvwill be understood that I do not limit myself to the particular mechanisms shown in this respect. v

Fig. 7 will nt into the diagrammatic view of Fig. 3 in the same way that Fig. 4 does, with the heat exchanger 66- omitted in this case because the single heat exchange coil 82 carrying warm liquid refrigerant through the housing |89 has been added.- In thesectional portion of Fig. 7 the plane of section of the bulb |08 and of the two tubes coiled around it is taken at the rear of the plane of the section through the two valve ports and parts 92 and |89 in order that the incoming ends of the tubes 69 and 10 may be shown as behind the vertical legs of the same tubes which connect with the ports controlled by the valves 82 and 83. It will be understood that the bulb |03 responds equally to temperature drops-of the helically wound portion of the tube 69 and to temperature drops of the helically wound portion of the tube 10, being exposed to an equal length of each at a uniform distance therefrom. The action is the same as in Fig. 4, where the bulb |08 contacts an equal length of each of the tubes 89 and 10.

When the bellows |60 contracts under pressure of the spring |6| in response to a drop of temperature of the volatile liquid in the bullb |03, the stem |64 moves upward with respect to the retaining wall |63 and the ten tooth ratchet wheel |66. The spring |65 is thus moved from the position seen in Figs. 7 and 8 to the position shown in Fig. 9. When the spring |65, in its upward travel, falls oi of the tooth against which it is bearing on the ratchet wheel |86 it strikes the end of the push rod |15 causing it to slide to the right in its bearing |16 and strike the 'leaf spring |10 which it moves to the right,

causing the contact |12 to snap away from the contact |13 against which it has been bearing under action of the spring |10. Contact |13, supported by the rigid arm |14, remains ilxed while the contact |12 moves away from it. 'Ihe arm |14 is electrically insulated by being supported by the insulating block |1|, but the contact |13 and the conductor ||0 may be insulated from arm |14 instead if desired. Likewise the contact |12 and the conductor may be insulated from the spring |10 by means of a washer and a bushing of non-conducting material..

The electrical connection between the conductors 0 and is broken by the contraction of the bellows in exactly the same manner that the contraction of the bellows |04 in Fig. 4 breaks the circuit therein, although through the medium of a different mechanism. Likewise the expansion of the bellows |60 due to stoppage of refrigeration will cause the opening of the valve 83 and the closing of the valve 82 as in the case of Fig. 4, through the medium of mechanism described below.

As the bellows |60 (Fig. 7) expands due to stoppage of refrigerating effect in both of the tubes 69 and 10 and because of the rise of air temperature resulting from stopping the compressor 86 (Fig. 3) it compresses the spring 6|, moving the stem |64 and fiat spring |65 downwardly from the position shown in Fig. 9 to the position shown in Fig. 8, rotating the ratchet wheel |66 and the gear |8| which is fixed for equal rotation with theratchet well |66, onetenth of a revolution. During this rotation a tooth of the ratchet wheel |66 engages the lug |11 on the end of the spring |10, -holding the contact 12 away from the contact |13, and at the end of the 36 .degrees of rotation the lug |11 drops into the next notch in the ratchet wheel |66, allowing the contact |12 to touch the contact |13, reclosing the circuit, which starts the motor 81 (Fig. 3) and operates the compressor.

During this counter-clockwise rotation of the gear |8| it has been rotating the pinion |82 with which it meshes. The ratio of teeth on the gear to teeth on the pinion is five to one, hence during 36 of gear movement the pinion will have moved or one-half of a revolution in a clockwise direction. It will be noted that no movement of the ratchet. wheel 66 has occurred between Figs. 8 and 9 since the only change has been the upward movement of the spring |65 and the resulting opening of the switch. During the next downward movement of the spring |65 to the position shown in Fig. 8, the ratchet wheel |66 and the gear |8| will have been moved, bringing the crank pin |83 i'lxed to the pinion |82 and the connecting'rod |84 to their extreme leftward positions (not shown), which will cause the rocker arm |86 (Fig. 7) to pivot upon its bearing concealed within the bellows |81, moving the point |88 to the extreme right, and carrying with it the lower end of the spring |33, which then acts upon the point 18 of the valve rocker 16 to open the valve 83 and close the valve 82.

The action is similar to that explained in connection with the construction illustrated in Fig. 4, in that the expansion of the bellows due to non-refrigeration of bulb |03 causes the valve mechanism to move, opening one valve and closing the one that has been open and then closing the switch, while the cooling of the bulb |03 which results from the closing of the switch and completion of an ice-forming period causes the bellows to contract until the pawl (here represented by the spring |65) falls into the next notch of the ratchet wheel and the circuit is opened. The spring 6| (Fig. 7) is provided with an adjustable seat at its lower end on the nut |62 which has a threaded engagement with the' member |63. The spring force eiective upon the movable end of the bellows |60 is thus adjustable for regulation of the cycles produced by this control mechanism. If desired, an additional spring or leverage adjustment may be provided in any of the well-known forms of such mechanisms for the purpose of making the temperature adjustments for range and for high and low limits separately and independently.

Fig. 10 is a duplication of Fig. 7 with the exception that some details have been omitted and the coils of tubes 69 and 10 are shown as sepa- .rately coiled, one about bulb |98 and the other about bulb |98. Both bulbs are connected with the same bellows |60. This view is shown to lillustrate a principle which may be employed in connection with a control of the nature described. In such a construction and with a charge of volatile fluid which is more than enough to ll one bulb in the liquid phase the bellows will respond to the temperature of the warmer bulb exactly as if the other bulb were not connected;

and with acharge of volatile fluid which is small d 9,145,777 i `lished by the warmest liquid in the system as soon as equilibrium is established.

y Should there be only one large bulb and one small bulb connected with the same bellows and the liquid charge be more than enough to lill the smaller bulb and less than enough to flll the large bulb the result would be that the bellows would always respond to the temperature of the larger bulb no matter which of the bulbs were the colder, for the liquid-vapor contact would always be in the larger bulb.

vFrom the above it will be clear that the construction shown lin Fig. 10 will operate in exactly the same manner as that shown in Fig. '7, expanding the bellows in accordance with the rise of air vtemperature when neither tubes 69 nor 10 are refrigerated and contracting the bellows in accordance with the temperature of the colder of the two tubes. This'principle applies equally to a system'inA which three bulbs are connected-with one bellows, so long as any one bulb will contain all of the volatile liquid with which the vconnected bulbs and bellows are'charged.

It will thus be seen that there might be three suction tubes instead of thetwo (69 and 10) ,with three bulbs instead of the'two (|98 and |99), and that the bellows |60 of Fig. 10 would act in response tothe vapor pressure established by the coldest of the three bulbs. Such a system will be described later in connection with Fig. 23, where three separate suction lines (23|, 232 and 233) have three seperate bulbs (32|, 325 and 323) associated A'with them and with a single control bellows.

Bulbs |98 and |99 are separately adjustable vertically to vary the iniluence of tubes coiled around them. Slotted ears |93, screws |34 and extra tapped holes |95 are provided for this purpose. This adjustment compensates for any inaccuraciesin the valve mechanism or diierences between the two evaporator sections, as does the adjustment of part |36 in Figs. 4, 5 and 6.

Fig. 11 is a sectional view through the axis of a valve mechanism designed to control three sucf tion passages in place of the two passages (tubes y 69 and 10)y seen in previous views. The operating mechanism seen at the vright of Fig. 11 is shown in Fig. l2, which may be considered a modified detail of Fig.A 10 with nine teeth on the ratchet wheel instead of ten. Fig. 13 is a section of Fig. 11 on the line `|3|3 Vthereof and conversely Fig..1l is taken on line'l of Fig. 13.

Referring to Figs.v 11 and 13 it is seen that there are three valves 2|1 carried by the tilting spider 2|6, which is pivoted upon the ball 2|3 of the stem -2I4 mounted upon the fixed spider 2|5,

v andthat for any given position of the arm 201 and the spring v208 there is but one of the valves 2|1 lifted from'its seat while the other two are held closed by the spring 208.

The arm 201 ls carried upon a shaft 205 (Figs. v1l and 12) ,.which is actuated by the pinion 204, best seen in Fig. 12. Ihe ratchet wheel 20| is actuated in the same manner as the ratchet wheel |66 shown in previous views, but it has nine teeth in place of ten, hence the shaft 202, with `which the ratchet wheel 20| is rigidly connected, turns one-ninth of a revolution or 40, instead of 36 as in the case ofshaft |61 in Figs. 7, 8 and 9v during each expansion of the bellows.

'I'he switch parts in Fig. 12 operate exactly as described in connection with Figs.'7, 8 and 9, but the gear 203 turns 40 during each warming up period. The pinion 204, driven by the gear f .203, has one-third as many teeth as the gear,

hence for each ratchet tooth of 20| the pinion 204 makes one-third of a revolution.

The shaft '266, upon which vthe pinion 204 is rigidly mounted, is thus turned through 120 each time that the bellows |60 expands during an idle period of the compressor 86, seen again in Fig. 23. Since this shaft 205 carries the arm 201, to the outer end of which one end of the spring 206 is connected by ball-and-socket joint, it will be understood that atthe end of each 120 movement of the arm 201, caused by an expansion of the bellows, the arm and the spring come to rest in a position which holds one of the three valves 2 I 1 open and the other two closed. At each 40 movement of the ratchet wheel the outer end of the spring 208 moves 120,causing the openvalve 2 |1 to snap shut and another of these three valves to open. Thus only one of the three suction tubes 22|, 222 and 223 is open to the interior of the housing 2 I8 at a time and the refrigerating effect produced by this tube on one of the three bulbs will cause the next contraction of the bellows |60.

Warm liquid refrigerant, passing through the tube 92' coiled within casing 2|8 (Fig. 11) gives up some of its heat to the cold vapor which enters through the open valve and exits to the suction tube 1|, thus maintaining the housing 2 I8 and associated parts at a temperature which prevents excessive frosting of the bellows 2| l, thus insuring that the bellows retains its flexibility.

'Ihe housing 2|8 is secured with bolts or suitable holding means to the wall 2|2 which sup-r ports the valve assembly, and a gasket between these parts makes the housing gasv tight. The operation of av triple valve mechanism such as is seen in Figs. 11, 12 and 13 by a bellows such as seen in Fig. 10, but with three bulbs and three suction tubes is believed to be well explained above, but for further clariilcation I show a slightly modified assembly in Figs. 14, 15 and 16.

The valve assembly 230 seen in Figs. 14, 15 and 16 is quite similar to the one shown in the three preceding views, but the spring 245 (Fig. 15), under compression, replaces the tension spring 208 of Fig. 11 and the operation is eected without the use of gears.

Referring to Fig. 15 it will be noted that the bulb 260, secured in intimate contact with the tubes 23|, 232 and 233 by means of the clamp 26| is connected through the tube 262 `to the interior of the bellows 263. This arrangement includes a charge of volatile uid of such volume that the entire liquid portion of the'charge may be contained in the bulb 260, hence the bellows 263 will have an internal pressure equal to the vapor pressure within the bulb 260. The result, as before explained, is the same `as if there were three bulbs 260, one contacting each of the three tubes 23|, 232 and 233, with the same quantity of volatile liquid and with all three bulbs connected with the interior of the bellows.

As shown in Fig. 15, the circuit including the wires and is open at the switch 261 and the bellows 263 is contracted, as would be the case immediately after the completion of a freezing period by the evaporator section connected with the tube 23|, which is shown with the valve 234 open so that refrigerant vapor is free to pass into the housing 24| of the valve mechanism and out through the tube 1|` to the suction side of the compressor.

The refrigerating effect of the tube 23| upon the bulb 260 has just caused the opening of the switch 261 andthe bulb 260, being no longer re- Y irigerated, will now warm up, approaching the temperature of air within the refrigerator. The resulting expansion of the bellows 263 will move the arm 254 upward at the right end, pushing.

downward on the pawl 253, which engages one of the three holes in the top of the ratchet wheel or disc 252, as shown in the plan view in Fig. 14. The relationship of these parts is such that the disc 252 will be moved in a counter-clockwise direction as viewed in Fig. 14 something more than 60 and less than 120 before the arm 254 has tilted the switch 261 to the position which recloses the circuit and starts the motor. `The movement of the disc 252 and shaft 250 causes the arm 248 and the point 241 to move correspondingly, since the arm 248 is secured'to the shaft 250 by means vof the set screw 249.

In any of the foregoing views, Figs. 4, 7, 10, 14, 15 and Fig. 1l with reference to Fig. 10, the switch might be shorted by connecting wire i|0 to wire ii i, or separating the switch as in Fig. 6. 'I'he ice making periods would then follow each `other consecutively in accordance with Fig. 24,

which will be described later.

After the point 241 has been moved something more than 60 and less than 120 and before the switch 2'61 has reclosed the electrical circuit, the spring 245 will have assumed an angle at which it will cause the stem 243 to tilt upon its pivot point 238 to close the valve 234 and open the valve 235 (Fig. 16). The release of thc spring pressure acting against the pawl 253, will under normal conditions, allow enough additional expansion of the bellows 263 to immediately move the switch 261 to the closed position, but in any event the switch will close soon after the valve mechanism has snapped to the new position.

The snapping over center of the spring 245, which is held in place solely by its pressure against the cups 246 which engage the two points of 243 and 241, will normally cause the ratchet disc 252 to move ahead, away from the propelling pawl 253, to nd a new point of rest midway between the two valves which it is now holding closed. Contraction of the bellows 263 caused by the cooling of the tube 232 which connects with the now open valve 235 and with the active evaporator section will gradually tilt the switch 261 toward the open position and will meanwhile lift the pawl 253 until it Afalls into the next hole in the top of the disc 252. The adjustment must be such that the pawl falls into the next hole before the switch closes the circuit again, as otherwise the next freezing period would be initiated in the same evaporator section which was last active.

At the third cycleof compressor operation the cooling effect will be on the third evaporator section with the valve 236 open and the bulb 2'60 will be cooled by the tube 233. The adjustment of the spring 285 by means of the screw 266 allows for setting the temperatures of operation. The control assembly 255 is provided with a cover 256, which is removed in Fig. 15. The wall 240 supports the valve mechanism and the housing 24| is secured thereto by means of screws with a gasket to insure a gas tight fit.

As in the case of the dual valve and two evaporator section designs, it is also permissible to separate the thermostatic switch from the valve actuating means, by merely taking the switch out of assembly 255 and providing a separate thermal switch, as is done in Fig. 6. 'Ihis would change the cycle of operation to that illustrated by the chartshown in Fig. 26, whereas the .cycle produced by a control of the type shown in Figs. 14,

15 and 16 is similar to that shown by the graph in Fig. 25. except that another curve would be added to F and G to represent the third evaporator section. A

Another method of separating the ice-making cycles from the thermostatic control of the condensing unit (motor and compressor) is to employ time actuated means as illustrated in Figs. 17 and 18 to control the refrigerant valves in the two or more suction passages and to add a separate thermostatic switch of conventional type to control the motor.

Referring to Fig. 17, the motor 210 drives the vertical shaft 21| on which there is a worm 212 driving the worm wheel 213, which is free to rotate upon the fixed horizontal shaft 214 (seen in Fig. 18). The planetary shaft 219 has its bearing in the worm gear 213 and keyed to this shaft.

which is free toV rotate in the worm wheel 213, are the gear 218 on one end and the gear 280 on the opposite end. 'Ihe gear 218 meshes with the fixed gear 211 and is driven thereby as the shaft 219 iscarried around the fixed shaft 214 by the worm gear 213. 'I'he gear 280, being keyed to the same shaft as gear 218, rotates with it and drives the smaller gear 28| (Fig. 18), which is free to rotate upon the xed shaft 214.

By selecting suitable numbers of teeth for these four spur gears it is possible to obtain a very great ratio of speed reduction between the worm wheel 213 and the driven gear 28| with its extending shaft 282 to which the arm 283 is keyed. Assuming that the fixed gear or pinion 211 has seventeen teeth; that gear218 has thirty-two teeth; that gear 280 is of a finer pitch and has fortynine teeth; and that the driven gear or pinion 28| has twenty-six teeth; the speed reduction may be calculated as follows:

rthreaded worm 212 with eighty teeth on the wheel 213 a reduction of eighty to one is obtained, making the total ratio of speed reduction 66,640 to 1.

Assuming a motor speed of 1750 R. P. M. it will be found that the gear 28|, shaft 282 and arm 283 will make one revolution in approximately thirtyseven minutes. When this period is divided into two parts, as in the case of a dual evaporator ice maker, employing a valve mechanism as shown in Fig. 7 with gear |82 mounted on shaft 282 of Fig. 18, it will provide about eighteen and one-half minutes of freezing time and an equal length of melting or ice-freezing time for each of the two evaporators of the ice maker. Should the shaft 282 be employed to drive the shaft 250 of Fig. 15 with no further gear reduction it would provide one-third of thirty-seven minutes, or twelve and one-third minutes of duration for forming ice with each of the three evaporators (see Fig. 23 for diagram of pipe connections). 'I'his latter combination allows twenty-four and two-thirds min- It is obvious that a ratio of one of Figs. 17v and `18 at the speeds above outlined,

ltwenty-fourand two-thirds minutes plusthree idle periods of probably twenty minutes each would result, or nearly an hour and a half of time for the ice blocks to free themselves from the surfaces upon which they have been frozen.

' This assumes that the chart in Fig. 25 be taken in view vof Fig. v23 to represent the cycle lof three evaporator sections, or in other words, inserting the idle period after each freezing period of the chart in Fig. 26. It alsoassumes that motor 218 is connected in parallel with motor-81 (Fig. 3 or 23) to re-start thermostatically after `it has stopped itself at the end of the freezing period of one of the evaporator sections, and that the switch is kicked off by the snap action of part 243 (Fig. 15).

In further explanation of Figs. 17 and 18 it should be noted that the shaft 21| may be extended above the motor (in the case of a condensing unit and control drive in a compartment below the refrigerated space) into the refrigerated space to drive the fan 289, which may be provided to circulate the air in the cabinet for the purpose of keeping' a more uniform air temperature and to assist-in defrosting or freeing'ice as disclosed in valves, shutters for control of air flow, etc.

outer end of arm 283.

my co-pending applications above identified. 'I'he shaft 288 may be locatedin vertical position as shown A or otherwise as required to actuate It is actuated by the means shown in Fig. 1 8 from the slow moving shaft 282 by means of the arm 283 and the spring 284. The arm 281 on one end (shown as the lower) of shaft 288 is connected with the arm 283 by means of the spring 284 with a ball 285 attached to one end of the spring and seated between two prongs of a fork 286 on the This end of spring 284 travels in the circle described by the outer end of the slowly revolving varm 283, causing the arm 281, to which the other end of the spring is attached, to move alternately to positions 281 and 281'. At the position shown in Fig. 18 the spring `284 would have moved the arm 281 to the position 281' and sometime before the shaftv 282 has turned another 180 the spring 284 will-cause the arm 281 to move back to the position shown by solid lines.

, It should be noted that the angular movementv 1 of the shaft 288 is stopped by the valve or shuttions possible between the elements of this invention areshown because these possibilities are too numerous to cover in detail, but it should be understood that all such combinations are within the scope of my invention.

It will be understood that the motor 218 of Fig. 17 may be of a horizontal instead of the vertical type shown and that suitable gears would allow the driven shaft 282 or the rocker shaft 288 to extend in any direction. The motor and gear mechanism may be located Within the refrigerated space-of a refrigerator cabinet if desired,

. since the heat output of the small motor required is negligible or almost so. The motor and gear mecahnism may be' located above or below or at one side of-therefrigerated space, according to c 3 9,145,711 A to um illustrateurs m. is driven by the gem details' of design. It is permissible to allow the vmotor 218 to operate continuously, or it may be wired in parallel with the motor 88' of the refrigerating system so that the gear drive is idle whenever the compressor is idle. 5

While the evaporators and ice water tank, cabinet, etc. employed with the present invention may be the saine as disclosed in any of my copending applications mentioned at the beginning of this speciflcatiomin Figs. 19, 20 and 21 is shown an improved form of ice water tank and evaporator particularly suited for use in this connection.

Referring to Fig. 19 the cabinet 8| will be recognized as a type covered by my previously identifiedl applications, particularly by Serial Number 697,124.

The clearance pocket H8 in the door for the lwater faucet H8' allows the tank to be located nearer to the door. 'Ihe drain pan'and trap construction for disposing of water assumes use of the disclosure in my co-pending application Serial No. 8,879, filed Feb. 21, 1935.

The tank 38| is here shown equipped with av removable lidl 382 which is fitted with a molded rubber gasket 383 embracing its margins to insure a substantially air-tight joint with the tank so that breathing of air into and out of the tank maybe minimized, protecting the ice and water within the tank from contamination with food80 odors and tastes. In order` that the cover 382 may be held securely and tightly in place at all times, except when it is lifted for the purposes of adding water to or removing ice from the tank, I have provided the toggle-clamping means which is described below.

The cover 382-is provided on its upper surface with two ears 384 (384 in open position) which provide bearings for a shaft which is rigidly connected with two links 381, one on either side of 40 the tank. Each of the two links 381 is hinged to a shorter link 388 by means of a pin which is integral with a knob 389 and the short links 388 are pivotally attached by pin 3|8 to an upright leg' of the forward hanger strap 386.

To lift the cover 382 and slide it rearward to the dotted position indicated at 382 one grasps the two knobs 388'and pulls them forward and upward till the shorter links 388 assume the position 388 shown in dotted lines. This causes the longer links 381 to assume the position 381' which is also shown by dotted lines, moving the ears 384 to the position '384' and the lid 382 to the position 382'. In this position the cover is well out of the Way, allowing easy access to the tank for removal of ice, which is accomplished by means of a perforatedscoop, wire ladle, or other suitable implement. The location of the tank and the form of the cabinet allow the user to pourV water into the tank from a pail or other container by 60 merely opening Je cabinet door and raising the tank lid as above described.

To facilitate this operation of raising the tank cover I have privided the Weight 385, attached to the cover 382 near its rear end. This weight 55 causes the cover to tilt to the. position shown by dotted lines when the cover is moved to the rear in opening it. The gasket 383 or other suitable soft material is arranged to stop the rearward movement of the cover by striking the rear lining of the cabinet when the cover moves to the open position, thus protecting the lining of the cabinet from damage in the event that the cover is opened quickly.

To close the tank it is only necessary to grasp u one or both of the knobs 309 and swing them down to the closed position, where the toggle locking action of the links 301 and 308 hold the cover tightly down on the tank `30 I. An extension of the hinge pin, of which knob 309 is the head, strikes the hanger 306, preventing the toggle levers from going too far over center in the closing movement. 'I'his clamping of the cover down on the tank also serves to aid in holding the tank itself down against the evaporator surfaces 3I9 (see Fig. 21) in good thermal contact therewith, since the hinge pins 3I0 are attached to the hanger 306 and not to the tank. Also, since none of this mechanism is attached to the tank itself, the tank may be removed by simply lifting the cover and pulling the tank forward out of the cabinet, which is an important feature in allowing the tank to be kept in g'ood sanitary condition.

It will be noted that the type of evaporator elements used in this construction allows the tank to be removed by a straight forward movement without lifting the tank up from the evaporator elements, as was necessary in some of the ideslgns disclosed in my earlier applications previouslyidentied herein. For shipment and handling of the cabinet assembly the tank and cover are securely clamped in position by merely closing the cover and clamping it with the toggle mechanism shown.

The weight of the tank and its contents and the force exerted downwardly on the tank by the cover clamping means cause the angular surfaces 59 of tank 30| to bear heavily against the evaporator surfaces 3I8 onthe two sides of the tank. 'I'hese surfac 3I8 are preferably flat and are formed upon the several evaporator units 3I5, which are individually 'supported pivotally upon one oi' the two supporting rods 3I2, of which there is one on each side of the tank. The rods 3I2 are rigidly clamped in holes in the hangers 306 by means of set screws 3| I, seen in Figs. 2O and 21. The rods 3I2 pass through the fins 3I1 of the several evaporator units 3I5 on their respective sides of the tank, but the holes in fins 3I1 provide a considerable clearance for the rods 3I2, so that each individual evaporator unit is not only free to rock upon its rod 3I2, but may move toward and away from the tank. A spring 3I3, located between each .evaporator unit and its rod 3I2, urges the surface 3 I8 against. the tank surface 59.

In order to provide a more definite thermal break between the evaporator units 3I5, fin units 296 are mounted upon the rods 3I2 alternately with the evaporator units 3I5, with springs 3I3 arranged to urge the fin units against the wall 59 of tank 30| in the same manner that the evaporator units are held against the tank.

While fins 3I1 of the evaporator units are small and are perforated to reduce their area of contact with air, the fins 298 of the fln units 296 are large and are not perforated except by the hole for the rod 3I2. The fin units 3 I 1 have about the same or even more area of contact with the tank than have evaporator units 3I5, but they have less vertical height adjacent to the tank than have the evaporator units in order that they may be free to rock upon the rod 3I2 without corntacting either of the manifold tubes 6I or 63.

A spring seat 299 (Fig. 20)l is located on each of the fin units 296 and an embossed spot of part 3 I9 on each of the evaporator units 3| 5 to receive and retain the corresponding ends of corresponding springs 3I3. Figure 19 shows ve evaporator units 3I5 and flve iln units 296 on the near (right hand) side of the tank, and there are equal numbers of each on the other side of the tank. 'I'he rear-most fin unit 296 might be omitted, but it serves to assist in freeing ice frozen by the rear evaporator unit 3I5. No fin unit is required or shown in front of the front evaporator unit N6 because its location is exposed to warmer air than is the rear unit.

The main refrigerating effect of evaporator units 3I5 is to cool the tank wall and the water within the tank. The fins 290 and the-outer surfaces of the tank 30| do most of the cooling of air within the cabinet and the heat picked up by flns 296 prevents ice blocks -I I1 from freezing together and aids in freeing them from the tank wall.

Although the various evaporator units are connected by means Aof manifold tubes (il-and 63, these tubes have a certain degree of exibility so that the springs 3I3 and the freedom of the evaporator units 3I5 to rock upon the rods 3I2 insure that each surface 3I8 makes a good thermal contact with the surface 59 of the tank. This is further aided by the fact that the tank is made of sheet metal having a certain degree of flexibility and by the water pressure within the tank resulting from the static head of water above these surfaces. The fiat surfaces, unlike the conical and spherical surfaces shown in some of my previous applications, allow for a small degree of flexibility which has been found in actual use to be ample for the purpose.

Attention is directed to the form of tank 30| by means of which the top forward lip of the tank allows easy pouring of water into the tank and ready access to floating ice without placing the entire front wall of the tank in such close proximity to the door that an excessive heat transmission from the door to the tank is allowed. Also the inclination of the rear wall of the tank allows the cover to be short enough to slide out of the way without sacrificing space at the rear of the tank. Wh-at little space is left at the rear of the tank. and below the path of the cover is utilized for location of control devices such as IOI Moisture condensed upon the tank, tubing and evaporator units drips into the pan 14 at each cycle, since any frost formed is melted during the defrosting period of each cycle. Water is drained from the pan 14 through the trap shown and out of the cabinet through the tube 12, after which it is preferably disposed of by the means disclosed in my co-pending application Serial Number 8,879, led February 21, 1935.

Figure 21 shows a baille 3I4, which may be employed to direct air currents more definitely over the fins 3| 1 and to shield the i'lns from dishes placed in the cabinet. Such bailles areshown supported from the hangers 306 in any suitable manner, allowing a small clearance between the baiiies and the fins.

It will be noted that the upper longitudinal corners of the sharp freezer 54 are rounded as indicated in Figs. 19 and 21. This facilitates air flow downward from the fins and aids in cooling the interior of the cabinet and freeing the ice frozen in the tank from the walls thereof as above described.

Figure 22 illustrates the progressive freezing, flrst of several small blocks II1 of ice on the inner surfaces of the tank 54, and then the large ice block II1 which is formed by growth and merging of the smaller ice blocks in the event that the freezing cycle is considerably prolonged. When such a large ice block is formed is it found that the ice breaksapart very-easily upon 'lines ill, where the smaller separate blocks join during the latter part of vthe freezing processto form the larger block. This is the result of a modi- `iled crystalline structure ofthe ice at the junctions II5, caused by the two separate crystalline structures meeting and in freezing together forcing a modified arrangement of crystals at the junction. Y Y

Fig. 23 is a diagrammatic representation of` a system employing a triple valve of a type' represented by Figs. 11 .to 16 inclusive, with three i evaporator sections instead of'two. 'I'he vevaporator units 3I5 are in this figure represented by the passages 3 I6, which can also be seen in Figs. and 2l, where these evaporating passages or spaces are enclosed between the walls .3i 8 (formed integrally with the flns 3i 1) and the sheet metal parts 3|9, which are soldered or otherwise attached in al gas-tight manner to the fins or the walls 3iil.l The tubes 6l and 63 are soldered to bothy parts and provided with openings for the passage of refrigerant intoand out of theevaporating spaces 3l6.

In Fig. 23 I have employed the numerals 6i to indicate the inlet manifold to one set of evaporating spaces 3|6, with numerals 6l'v to indicate the inlet manifold to another set, and-6|" indieating the inlet manifolds tov the third set of evaporating units which lare arranged in two groups, one on eitherv side of the'tank for conv enient utilization of the tank areas 59. The refrigerant circuit is described as follows:

Starting with .the compressor 86 the high presn `sure refrigerant vapor passes through the tube 88 to the condenser 89, where-it is condensed to afliquid and flows into the receiver 90. The liquid passes through the tubev 9| to the tube 93 4and then to the restricting device or expansion valve 94 at which point it is reduced in pressure and delivered through the tube 95 to the sharp freezer 54, where part of the liquid is evaporated.

` From the sharp freezer the refrigerant, now partially vaporized, goesA through the tube 96 to the tubes 326 and 321 since the outlet through the tubes 328 and 329 is yblocked at the moment by valves 235 and 236, which are closed. rIfhe refrigerant now enters the several evaporator units r fed by manifolds 6 i and is further vaporized be-` fore it ows'out through manifolds 63" to the tube 23|. It now enters the valve assembly 230, which is seen in greaterdetail in Figs. 14, -15

and I6, through the valve port opened by the lifting of the valve 234 from its seat. The heat exchanger 'between liquid and vapor tubesV is omitted'in this diagrammatic view as being a detail which is only required under certain con- -ditions and with certain refrigerants, andr being a more or less conventional item.

by motor 81. `line conductors HI and H2 as shown before From the housing of valve assembly 230 the' vapor exits through tube-1| and returns to the suction side of compressor 86, which is driven The wiring diagram includes the and the circuit is controlled by the thermostatic control 255, which is seen in detail in Figs. 14

e and 15. This control actuates both theV switch andthe valve mechanism as before described.

The mechanical connection between the' ratchet wheel or disc 252 (Fig. 23) and the valve assemexplained,'-the action of control 2li is the same for either of these two arrangements, so long as the volatile charge of the control is such that all ofthe liquid may be contained in one of the bulbs of Fig..23. There is a slight advantage in the'use of three bulbs located remotely from each other in the fact that this obviates a certain amount of the overlapping of temperature drops and rises of the three suction tubes in their effects upon the single bulb 260, but either construction is practicablev and can be arranged to produce the desired results:

.After the switch of 255 has opened and the valves have been actuated to close the valve 234 and open the valve 235, and the switch has reclosed, starting the motor 81, the flow of refrigerant from the tube 96 to the valve assembly 230 is diverted to pass through the tube 328, manifold .6i the evaporating spaces 3| 6 associated therewith, the manifold y63 and through the port of the valve 235. During the next running period of the motor and compressor, this flow will be again diverted to tube 329, manifold 5i', the associated spaces 3l6,.manifold 83 and through the port opened by the valve 236.

'I'he number of evaporator units served during each of these three running periods is preferably It is constant, though not -so shown in Fig. 23. obvious that the evaporator units might be operated in fourgroups instead of three,y with two groups on each side of the tank and a quadruple valve designed for opening only one oi' the four valves at a time. Such ay quadruple system is considered to be within the scope of this applicationand so obvious therefrom that no additional drawing is needed to disclose it.

Figs. 24, 25 and 26 are shown for the purpose of explaining in graphicform the operating cycles of the various constructions disclosed in the preceding views. Some of these cycles of operation are possible with apparatus which has been disclosed in the co-pending applications mentioned at the beginning of this specification and there are cycles not illustrated by graphs which are possible with the apparatus herein disclosed, but these graphs should serve to clarify any faults of description or inadvertent omissions of details from my descriptions'of the foregoing figures.

In Fig. 24 temperatures in degrees Fahrenheit are marked off by horizontal lines in accordance with the scale of figures at the leftside of the v graph, while time in minutes is indicated by the figures appearing at the top of the figure. The broken line A plots variations in temperature of air within the refrigerator employihga control similar to that shown in Fig. 6 wherein the icemaking cycles and the condensing-unit cycles are separately controlled.

' The broken lineB indicates typical temperature variations of one ofthe two evaporator sections or of one of the two suction passages, for

instance, the tube 10 of Fig. 6. The solid curve C marks the temperature changes of the other suction passage, for instance, the tube r69 of Fig.

6. The dot and dash line D indicates `typical resultant temperature changes of the bulb |40 in Fig. 6.

Starting at the left of Fig'. 24'withsthe downward curve 'of B resulting from refrigeration in the evaporator section served by the suction tube 10, leading to the open valve in the'assembly 15, it will be noted that the temperature drops to alciout'fivel degrees, pulling the temperature of .the bulb I4li-down to slightly below l0 degrees while the temperature of the tube-69, as indicated by the curve C rises to 32 degrees or higher. The drop of bulb temperature causes the valve mechanismy (shown in Fig. 6 with reference to Fig. 4) to operate, opening the valve 03 controlling the tube 69 and closing the valve 82A controlling the tube 10Q This immediately stops refrigeration of' one evaporator section and of the tube 'l0 and starts refrigeration of the other evaporator section and to a lesser degree of the tube 69. This allows the bulb (curve D) to warm up, since it will'take several minutes for the frost-back" of the tube 69 to produce much effect -upon the temperature of the bulb |40.

The bulb |40 being exposed to air temperature, warms up more rapidly than the tube l0 for eight minutes as shown on the chart, but then the frost-back begins to produce its effect and the temperature of bulb |40 drops quite rapidly for a fewminutes and the curve then ilattens out, falling radually to the ,kick-over" temperature of about 9 degrees at the end of the second 20 minute period, which again starts refrigeration in the original evaporator section and the curve B begins to drop.

Without some control of air temperature within the cabinet, this cycling would go on until the air within the cabinet had been pulled down to so lowv a temperature that the ice would not be melted free from the surface upon which it is frozen in time to allow for the next freezing cycle on that side of the tank. The result would be that ice would continue to build up on each side of the tank in large blocks which would eventually join in the middle of the tank and make one large piece of ice, which would not be conveniently usable. This result is avoided by the use of a thermostatic control-similar to those in common use for controlling refrigerating systems, but in this case operating on cabinet air temperature for the purpose of stopping the condensing unit before the air in the cabinet has dropped to so low a temperature that the ice blocks are in danger of `failing to release at each non-freezing period, while ice is being frozen on the opposite side of the tank.

On the vertical line marked by minutes in Fig. 24 we see that the cabinet air temperature has fallen;` to about 42 degrees and that at this point ythe switch was opened by the temperature drop of the bulb |52, causing all of the curves of the graph tov assumevupwa'rd trends. This will continue until the air temperature rises to some predetermined limit, preferably below 50 degrees, at which temperature limit the switch of control |54 re-closes and cycling ofthe ice-maker will resume at the point it left off, pulling the curve B downward again on a freezing period which was interrupted by the cutting out of the thermostatic switch and pulling the other curves down more gradually.

Fig. 25 represents the cyclic operation of a system using a control similar to that illustrated in Fig. 4,` where an idle period of the condensing unit occurs at the end of each freezing period on one side of the tank. This provides a greater period of time for melting the ice free after leach freezing period by utilizing the idle time of the condensing unit between freezing periods instead of havinglong idle periods of the condensing unit at less frequent intervals.

The coordinates of thisvgraph are similar to thosel of Fig; 24 except that the time scale is L'more condensed to show 240 minutes of operation-instead of minutes. The broken line E indicates cabinet air temperature, which is held ausm? within closer limits than in Fig. 24. Solid line F is a curve representing the temperature of one evaporator section; broken line G is the curve of temperature of the other evaporator section; and curve H represents the temperature of control bulb |03 in Fig. 4.

Starting with the four curves at the left of Fig. 25 it will be noted that all are rising, indicating that the motor is idle. At the end of the first 40 minutes the bulb temperature, as indicated by the curve-H,has risen to about 42 degrees, approaching the 44 degree temperature of the air in the cabinet. This is the cut-in point of the control and refrigeration starts with the control in the position shown in Fig. 4, refrigerating the evaporator section served by the suction tube 10 and the open port of the valve 02. Thus the curve F may be taken as representing the Ytemperature of this evaporator section. This temperature drops rapidly, but ilattens out toward the end of the twenty minute running period, at which time the temperature of the bulb |03 has fallen to about nine degrees and the switch |09 opens, stopping the motor and compressor. During this running period the cabinet air temperature has dropped from about 44 degrees to about 42 degrees, but this drop has no appreciable effect upon the control, which operates upon the temperature of the bulb |03. This bulb temperature approaches, but does not Afall so low as the temperature of the active evaporator section represented by the curve F.

Now that the refrigerating system has been stopped the temperatures all rise and the bulb (curve H) approaches the temperature of the air in the cabinet, which has in about forty-five minutes of idle time reached approximately 44 degrees again. The bulb, having risen to about 42 degrees causes the bellows |04 to expand, actuating the valve mechanism to open the valve 83 minute period) has minutes in which to free itself from the wall of the tank, since refrigeration is not again started on this side of the tank until the minute line is reached. The time allowed for melting ice free is the idle time following the freezing plus the freezing time on the other side plus the idle time following the freezing on the other side of the tank. The time will vary according to the rapidity with which the cabinet warms up, cutting down the idle time and the total time for melting the ice free when the weather is warm or considerable warm food is placed in the cabinet or the cabinet door is opened frequently. 'I'his produces more ice when it is needed and provides more time for melting the ice free when the temperature is low and more time is required for that purpose. This principle of control which causes the refrigeration to start with a rise of cabinet air temperature and stops refrigeration in response to a drop of temperature which goes with the finishing of the freezing of ice on one side of the tank or one section of the tank is here employed to great advantage by causing the valve mechanism to operate during the warming-up or idle period. 

